The role of haemoglobin mass on VO(2)max following normobaric 'live high-train low' in endurance-trained athletes

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The role of haemoglobin mass on VO(2)max following normobaric 'live high-train low' in endurance-trained athletes. / Robach, Paul; Siebenmann, Christoph; Jacobs, Robert A; Rasmussen, Peter; Nordsborg, Nikolai; Pesta, Dominik; Gnaiger, Erich; Díaz, Víctor; Christ, Andreas; Fiedler, Julia; Crivelli, Nadine; Secher, Niels H; Pichon, Aurélien; Maggiorini, Marco; Lundby, Carsten.

I: British Journal of Sports Medicine, Bind 46, Nr. 11, 2012, s. 822-827.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Robach, P, Siebenmann, C, Jacobs, RA, Rasmussen, P, Nordsborg, N, Pesta, D, Gnaiger, E, Díaz, V, Christ, A, Fiedler, J, Crivelli, N, Secher, NH, Pichon, A, Maggiorini, M & Lundby, C 2012, 'The role of haemoglobin mass on VO(2)max following normobaric 'live high-train low' in endurance-trained athletes', British Journal of Sports Medicine, bind 46, nr. 11, s. 822-827. https://doi.org/10.1136/bjsports-2012-091078

APA

Robach, P., Siebenmann, C., Jacobs, R. A., Rasmussen, P., Nordsborg, N., Pesta, D., Gnaiger, E., Díaz, V., Christ, A., Fiedler, J., Crivelli, N., Secher, N. H., Pichon, A., Maggiorini, M., & Lundby, C. (2012). The role of haemoglobin mass on VO(2)max following normobaric 'live high-train low' in endurance-trained athletes. British Journal of Sports Medicine, 46(11), 822-827. https://doi.org/10.1136/bjsports-2012-091078

Vancouver

Robach P, Siebenmann C, Jacobs RA, Rasmussen P, Nordsborg N, Pesta D o.a. The role of haemoglobin mass on VO(2)max following normobaric 'live high-train low' in endurance-trained athletes. British Journal of Sports Medicine. 2012;46(11):822-827. https://doi.org/10.1136/bjsports-2012-091078

Author

Robach, Paul ; Siebenmann, Christoph ; Jacobs, Robert A ; Rasmussen, Peter ; Nordsborg, Nikolai ; Pesta, Dominik ; Gnaiger, Erich ; Díaz, Víctor ; Christ, Andreas ; Fiedler, Julia ; Crivelli, Nadine ; Secher, Niels H ; Pichon, Aurélien ; Maggiorini, Marco ; Lundby, Carsten. / The role of haemoglobin mass on VO(2)max following normobaric 'live high-train low' in endurance-trained athletes. I: British Journal of Sports Medicine. 2012 ; Bind 46, Nr. 11. s. 822-827.

Bibtex

@article{266bbdb4b491416fbd59f0ce67706b8c,
title = "The role of haemoglobin mass on VO(2)max following normobaric 'live high-train low' in endurance-trained athletes",
abstract = "It remains unclear by which mechanism 'live high-train low' (LHTL) altitude training increases exercise performance. Haematological and skeletal muscle adaptations have both been proposed. To test the hypotheses that (i) LHTL improves maximal oxygen uptake (VO(2)max) and (ii) this improvement is related to hypoxia-induced increases in total haemoglobin mass (Hb(mass)) and not to improved maximal oxidative capacity of skeletal muscle, we determined VO(2)max before LHTL and after LHTL, before and after the altitude-induced increases in Hb(mass) (measured by carbon-monoxide rebreathing) had been abolished by isovolumic haemodilution. We obtained skeletal muscle biopsies to quantify mitochondrial oxidative capacity and efficiency. Sixteen endurance-trained athletes were assigned (double-blinded, placebo controlled) to =16 h/day over 4 weeks to normoxia (placebo, n=6) or normobaric hypoxia equivalent to 3000 m altitude (LHTL, n=10). Four-week LHTL did not increase VO(2)max, irrespective of treatment (LHTL: 1.5%; placebo: 2.0%). Hb(mass) was slightly increased (4.6%) in 5 (of 10) LHTL subjects but this was not accompanied by a concurrent increase in VO(2)max. In the subjects demonstrating an increase in Hb(mass), isovolumic haemodilution elicited a 5.8% decrease in VO(2)max. Cycling efficiency was altered neither with time nor by LHTL. Neither maximal capacity of oxidative phosphorylation nor mitochondrial efficiency was modified by time or LHTL. The present results suggest that LHTL has no positive effect on VO(2)max in endurance-trained athletes because (i) muscle maximal oxidative capacity is not improved following LHTL and (ii) erythrocyte volume expansion after LHTL, if any, is too small to alter O(2) transport.",
author = "Paul Robach and Christoph Siebenmann and Jacobs, {Robert A} and Peter Rasmussen and Nikolai Nordsborg and Dominik Pesta and Erich Gnaiger and V{\'i}ctor D{\'i}az and Andreas Christ and Julia Fiedler and Nadine Crivelli and Secher, {Niels H} and Aur{\'e}lien Pichon and Marco Maggiorini and Carsten Lundby",
note = "CURIS 2012 5200 135",
year = "2012",
doi = "10.1136/bjsports-2012-091078",
language = "English",
volume = "46",
pages = "822--827",
journal = "British Journal of Sports Medicine",
issn = "0306-3674",
publisher = "B M J Group",
number = "11",

}

RIS

TY - JOUR

T1 - The role of haemoglobin mass on VO(2)max following normobaric 'live high-train low' in endurance-trained athletes

AU - Robach, Paul

AU - Siebenmann, Christoph

AU - Jacobs, Robert A

AU - Rasmussen, Peter

AU - Nordsborg, Nikolai

AU - Pesta, Dominik

AU - Gnaiger, Erich

AU - Díaz, Víctor

AU - Christ, Andreas

AU - Fiedler, Julia

AU - Crivelli, Nadine

AU - Secher, Niels H

AU - Pichon, Aurélien

AU - Maggiorini, Marco

AU - Lundby, Carsten

N1 - CURIS 2012 5200 135

PY - 2012

Y1 - 2012

N2 - It remains unclear by which mechanism 'live high-train low' (LHTL) altitude training increases exercise performance. Haematological and skeletal muscle adaptations have both been proposed. To test the hypotheses that (i) LHTL improves maximal oxygen uptake (VO(2)max) and (ii) this improvement is related to hypoxia-induced increases in total haemoglobin mass (Hb(mass)) and not to improved maximal oxidative capacity of skeletal muscle, we determined VO(2)max before LHTL and after LHTL, before and after the altitude-induced increases in Hb(mass) (measured by carbon-monoxide rebreathing) had been abolished by isovolumic haemodilution. We obtained skeletal muscle biopsies to quantify mitochondrial oxidative capacity and efficiency. Sixteen endurance-trained athletes were assigned (double-blinded, placebo controlled) to =16 h/day over 4 weeks to normoxia (placebo, n=6) or normobaric hypoxia equivalent to 3000 m altitude (LHTL, n=10). Four-week LHTL did not increase VO(2)max, irrespective of treatment (LHTL: 1.5%; placebo: 2.0%). Hb(mass) was slightly increased (4.6%) in 5 (of 10) LHTL subjects but this was not accompanied by a concurrent increase in VO(2)max. In the subjects demonstrating an increase in Hb(mass), isovolumic haemodilution elicited a 5.8% decrease in VO(2)max. Cycling efficiency was altered neither with time nor by LHTL. Neither maximal capacity of oxidative phosphorylation nor mitochondrial efficiency was modified by time or LHTL. The present results suggest that LHTL has no positive effect on VO(2)max in endurance-trained athletes because (i) muscle maximal oxidative capacity is not improved following LHTL and (ii) erythrocyte volume expansion after LHTL, if any, is too small to alter O(2) transport.

AB - It remains unclear by which mechanism 'live high-train low' (LHTL) altitude training increases exercise performance. Haematological and skeletal muscle adaptations have both been proposed. To test the hypotheses that (i) LHTL improves maximal oxygen uptake (VO(2)max) and (ii) this improvement is related to hypoxia-induced increases in total haemoglobin mass (Hb(mass)) and not to improved maximal oxidative capacity of skeletal muscle, we determined VO(2)max before LHTL and after LHTL, before and after the altitude-induced increases in Hb(mass) (measured by carbon-monoxide rebreathing) had been abolished by isovolumic haemodilution. We obtained skeletal muscle biopsies to quantify mitochondrial oxidative capacity and efficiency. Sixteen endurance-trained athletes were assigned (double-blinded, placebo controlled) to =16 h/day over 4 weeks to normoxia (placebo, n=6) or normobaric hypoxia equivalent to 3000 m altitude (LHTL, n=10). Four-week LHTL did not increase VO(2)max, irrespective of treatment (LHTL: 1.5%; placebo: 2.0%). Hb(mass) was slightly increased (4.6%) in 5 (of 10) LHTL subjects but this was not accompanied by a concurrent increase in VO(2)max. In the subjects demonstrating an increase in Hb(mass), isovolumic haemodilution elicited a 5.8% decrease in VO(2)max. Cycling efficiency was altered neither with time nor by LHTL. Neither maximal capacity of oxidative phosphorylation nor mitochondrial efficiency was modified by time or LHTL. The present results suggest that LHTL has no positive effect on VO(2)max in endurance-trained athletes because (i) muscle maximal oxidative capacity is not improved following LHTL and (ii) erythrocyte volume expansion after LHTL, if any, is too small to alter O(2) transport.

U2 - 10.1136/bjsports-2012-091078

DO - 10.1136/bjsports-2012-091078

M3 - Journal article

C2 - 22790809

VL - 46

SP - 822

EP - 827

JO - British Journal of Sports Medicine

JF - British Journal of Sports Medicine

SN - 0306-3674

IS - 11

ER -

ID: 41812355